WO2007020162A1 - Cooking appliance - Google Patents

Abstract

The invention relates to a cooking appliance, in particular, a cooking appliance which is mounted at an elevated level, comprising at least one muffle which defines a cooking area (3), and the muffle opening thereof (6) is surrounded by a muffle frame, a door (7) which closes the muffle opening and a drive device (9, 10) which is used to drive the door and which is controlled by a control circuit (13). The drive device can be controlled by the control circuit in such a manner that a predetermined driving parameter of the door can be controlled by at least one defined ramp.

Description

 Garqerät

The present invention relates to a cooking appliance, in particular a Hocheinbau- cooking appliance, with at least one a cooking chamber delimiting muffle with a muffle opening, a door to close the muffle opening and controlled by a control device drive means for moving the door.

From US 2,944,540 a high-installation cooking appliance is known in which a bottom door is moved by means of an electric motor.

For example, in DE 101 64 235 A1 and DE 101 64 239 A1 a Hocheinbau- cooking appliance is described with an electric motor-driven floor door, which has a E lektrostromsensor.

The procedure of the bottom door is done in the known devices by turning on or off the drive motor, d. H. in that a certain voltage is applied to or disconnected from the motor.

The disadvantage here is that the uneven due to the sudden switching on and off of the drive motor, the bottom door, z. B. jerky, anfährt or decelerates. This backlash appears uncomfortable to the operator and can also lead to spilling food.

It is therefore the object of the present invention to provide a cooking appliance of the type described above with an improved, in particular more uniform, travel behavior.

The present object is achieved by the cooking appliance having the features of patent claim 1 and a method according to claim 13.

For this purpose, the cooking appliance, in particular a high-installation cooking appliance, equipped so that the Antriebssein direction by the control circuit is so controlled or regulated that a predetermined Verfahrparameter the door, z. B. a desired motor voltage or setpoint speed, by at least one defined Ram- pe, z. B. a voltage or speed ramp, can be controlled. An undefined, caused by simply switching on the drive motor, often disgusting, starting behavior is thereby avoided. The shape of the ramps is not limited, z. B. on a linear shape, and may also be multi-level.

It is advantageous, inter alia for increased user-friendliness, if the travel parameter is a travel speed of the door, that is, the door is speed-dependent and not load-dependent. In order for the door to move smoothly and without jerking when the door approaches, a setpoint speed to be reached is traversed by means of a first defined speed ramp. The movement of the door is then also independent of, for example, a payload or a change in the mechanical friction conditions. For example, the acceleration and / or the time to reach the desired speed and so on can be defined. Of course, if the travel distance is too short to reach a desired speed, the ramps may merge into one another even at lower speeds.

It may be favorable, although at a stopping of the door to a further, lower target speed, z. B. in the standstill, a second defined speed ramp, now with negative acceleration, can be moved through. This is more user friendly than an abrupt stop, e.g. B. by a short-circuiting of the drive motor.

If several target speeds are to be traversed in succession, then several ramps are to be passed through accordingly. The ramps basically do not need to have the same shape or slope (eg absolute).

In particular, in an automatic mode, it is advantageous if the door can - after a short drive - actuate a movement panel by means of the first speed ramp to a desired speed and automatically comes to a standstill of the second speed ramp.

In particular, in a manual operation, it is advantageous for improved reliability when the door during an operation at least one Verfahrschaltfeldes - advantageously both traversing panels simultaneously - using the first speed ramp moves to a desired speed and comes abruptly after releasing at least one traversing panel to a standstill. For ease of implementation and high measurement accuracy, it is advantageous if the travel speed can be detected by means of a speed measuring device which comprises at least one sensor arranged on a motor shaft of a drive motor of the drive device, in particular a Hall sensor. In this case, the speed measuring device can measure the speed of the door either directly, z. B. by arrangement on the door, or by indirect determination, for. B. by measuring the speed of a shaft, such as the motor shaft. The motor shaft can also be mounted in front of or behind a gearbox.

It is favorable for increased user-friendliness if the travel speed is user-adjustable. For example, the travel speed can be set by selecting from at least two speed levels, whereby the speed levels can also be preset at the factory. In particular, for older users, it is advantageous if the travel speed at least between a first, lower speed level in the range of 40 mm / s to 55 mm / s, in particular 50 mm / s, and a second speed level in the range of 60 mm / s to 80 mm / s, in particular in the range of 65 mm / s to 75 mm / s, in particular of 65 mm / s, can be switched. For an increase in operational safety and customer satisfaction, it is advantageous if a preset travel speed corresponds to the lowest speed level. In order for a user not to have to reset the setting of the traversing speed (s) each time the machine is switched on, the user-defined traversing speed can be stored in a non-volatile memory, eg a non-volatile memory. As an EEPROM, are stored.

In the case of a speed-dependent control, it is also advantageous if trapping on the door can be detected by monitoring the traversing speed, wherein the trapping protection is advantageously activated only when the setpoint speed of the door has been reached.

In particular when closing the cooking chamber or through the base door, it may be favorable if the movement of movement of the door can be switched between a speed-dependent traversing movement and a load-dependent or force-dependent traversing movement. The invention is particularly suitable for high-installation cooking appliances, in which the muffle opening is a bottom-side muffle opening, and the door is a bottom door, which preferably moves linearly.

The invention will be described in more detail below with reference to the attached schematic figures. Show it:

1 is a perspective view of a mounted on a wall Hoch- built-in appliance with lowered bottom door. 2 is a perspective view of the high-Einhaugargeräts with closed bottom door.

3 is a perspective view of a housing of the Hoch-Einbaugargeräts without the bottom door. 4 shows a schematic side view in a sectional view along the line I-I from FIG. 1 of the wall mounted high-mounted cooking appliance with lowered bottom door;

5 shows a front view of another embodiment of a high-installation cooking appliance; 6 to 11 are diagrams of movements of a floor door under various boundary conditions;

FIGS. 12 and 13 force time profile curves for a floor door.

1 shows a high-installation cooking appliance with a housing 1 is shown. The back of the housing 1 is mounted on a wall 2 in the manner of a hanging cabinet. In the housing 1, a cooking chamber 3 is defined, which can be controlled via a front side in the housing 1 introduced viewing window 4. In FIG. 4 it can be seen that the cooking space 3 is delimited by a muffle 5, which is provided with a heat-insulating sheath, not shown, and that the muffle 5 has a bottom-side muffle opening 6. The muffle opening 6 can be closed with a bottom door 7. In Fig. 1, the bottom door 7 is shown lowered, being with its underside in contact with a worktop 8 a kitchen device. In order to close the cooking chamber 3, the bottom door 7 is in the position shown in FIG. 2, the so-called. "Zero position" to adjust. To adjust the bottom door 7, the Hoch-Einbaugargerät a drive device 9, 10 on. The drive device 9, 10 has a drive motor 9 shown in dashed lines in FIGS. 1, 2 and 4, which is arranged between the muffle 5 and an outer wall of the housing 1. The drive motor 9 is in the region of the back of the Housing 1 is arranged and is, as shown in FIGS. 1 or 4, in operative connection with a pair of lifting elements 10, which are connected to the bottom door 7. 4, each lifting element 10 is designed as an L-shaped carrier, whose vertical leg extends from the housing-side drive motor 9 To adjust the bottom door 7, the drive motor 9 can be actuated by means of a control panel 12 and a control circuit 13, which is arranged according to FIGS. 1 and 2 at the front of the bottom door 7. As shown in Fig. 4, the control circuit 13 is located behind the control panel 12 within the bottom door 7. The control circuit 13, which here consists of several spatially and functionally separated and communicating via a communication bus circuit boards, provides a central control unit for the Device operation is and controls and / or controls z. As a heating, a method of the bottom door 3, a conversion of user input, a lighting, a pinch protection, a clocking of the radiator 16, 17, 18, 22 and much more.

FIG. 1 shows that an upper side of the bottom door 7 has a hob 15. Almost the entire surface of the hob 15 is occupied by radiators 16, 17, 18, which are indicated in phantom in Fig. 1. In Fig. 1, the radiator 16, 17 are two spaced apart, different sized cooking hob, while the radiator 18 is provided between the two cooking area heaters 16,17 surface heating element, which almost encloses the cooking area heaters 16, 17. The hotplate heaters 16, 17 define for the user associated cooking zones or hobs; the hotplate heaters 16, 17 together with the surface heating element 18 define a lower heat zone. The zones may be indicated by a suitable decoration on the surface. The radiators 16, 17, 18 are each controlled via the control circuit 13.

In the exemplary embodiment shown, the radiators 16, 17, 18 are configured as radiant heaters, which are covered by a glass ceramic plate 19. The glass-ceramic plate 19 has approximately the dimensions of the upper side of the bottom door 7. The glass-ceramic plate 19 is furthermore equipped with mounting openings (not shown) through which pedestals for holding support parts 20 for food carriers 21 protrude, as also shown in FIG. 4. Instead of a glass ceramic plate 19, other - preferably quick-responding - covers can be used, for. B. a thin sheet. With the help of a control panel 12 provided in the control knob, the high-installation cooking appliance can be switched to a cooking or a bottom heat mode, which will be explained below.

In the hob mode, the cooking surface heaters 16, 17 can be controlled individually by means of control elements 11, which are provided in the control panel 12, via the control circuit 13, while the surface heating element 18 remains out of operation. The hotplate mode is executable with the bottom door 7 lowered, as shown in FIG. But it can also be operated with closed cooking chamber 3 with raised floor door 7 in an energy saving function.

In the lower heat mode, not only the hotplate heaters 16, 17 but also the surface heating element 18 are actuated by the control device 13.

In order to achieve the most uniform possible tanning image of the food during the bottom heat, it is crucial that the cooking surface 15 providing the bottom heat has a uniform distribution of the heat output over the surface of the hob 15, although the heating elements 16, 17, 18 have different nominal powers. Preferably, therefore, the radiators 16, 17, 18 are not switched by the control circuit 13 to a continuous operation, but the power supply to the radiators 16, 17, 18 is clocked. The different sized nominal heating powers of the radiator 16, 17, 18 are individually reduced so that the radiators 16, 17, 18 provide a uniform over the surface of the hob 15 distribution of the heat output.

Fig. 4 shows schematically the position of a fan 23, z. B. for generating circulating air in a hot air operation or for supplying fresh air. In addition, a mounted on an upper side of the muffle 5 Oberhitzeheizkörper 22 is provided, the single-circuit or mehrkreisig, z. B. with an inner and an outer circle, can be executed. Also can - not shown here for clarity - another radiator such as a ring heater between the rear wall of the housing 1 and the muffle be present. By the control circuit 13, the various operating modes, such as, for example, top heat, hot air or Schnellaufheizbetrieb by an appropriate activation and adjustment of the heating power of the radiator 16, 17, 18, 22, possibly with activation of Fan 23, to be adjusted. The adjustment of the heating power can be done by appropriate timing. In addition, the hob 15 can also be designed differently, for. B. with or without roasting zone, as a pure - one or mehrkreisige - warming zone without cooktops and so on. The housing 1 has a seal 24 towards the bottom door 7.

The control panel 12 is arranged mainly at the front of the bottom door 7. There are alternatively other arrangements conceivable, for. B. at the front of the housing 1, divided into different sub-fields and / or partially on side surfaces of the cooking appliance. Further designs are possible. The controls 11 are not limited in their design and can, for. B. z. As control knob, toggle switch, pushbuttons and membrane keys include the display elements 14 include z. B. LED, LCD and / or touchscreen displays.

In Fig. 5 is schematically and not to scale a high-mounted cooking appliance shown from the front, in which the bottom door 7 is open on contact with the worktop 8. The closed state is shown in dashed lines.

In this embodiment, two traversing panels 25 are located on the front side of the fixed housing 1. Each traversing panel 25 comprises two pushbuttons, namely an upper CLOSE button 25a for a bottom door 7 traveling upwards in the closing direction and a lower OPEN button 25b for one Without automatic operation (see below) moves the bottom door 7 only by continuous simultaneous pressing the CLOSE buttons 25a both traversing panels 25 upwards, if possible; also moves the bottom door 7 only by continuous simultaneous pressing of the UP buttons 25b both traversing panels 25 down, if possible (manual operation). Since in manual operation an increased user attention is given to the user and also both hands are used here, an anti-trap protection is then only optional. In an alternative embodiment, shifting panels 26 are mounted on opposite outer sides of the housing 1 with corresponding ZU buttons 26a and UP buttons 26b, as shown in dotted lines.

The dot-dashed control circuit 13, which is located inside the bottom door 7 behind the control panel 12, the drive motor 9 so, that the bottom door 7 anfährt gently, ie not abruptly by simply hiring the drive motor 9, but by means of a defined ramp.

In this exemplary embodiment, the control circuit 13 comprises a memory unit 27 for storing at least one destination or travel position PO, P1, P2, PZ of the bottom door 7, preferably with volatile memory modules, eg. B. DRAMs. If a target position PO, P1, P2, PZ is stored, the bottom door can move independently after pressing one of the keys 25a, 25b or 26a, 26b of the traversing panels 25 and 26 in the set direction until the next target position is reached or one of the buttons 25a, 25b or 26a, 26b is pressed again (automatic mode). In this embodiment, the lowest target position PZ corresponds to the maximum opening, the (zero) position PO to the closed state, and P1 and P2 are freely adjustable intermediate positions. If the last target position for one direction has been reached, manual operation must also be continued if this is possible (ie the last end positions do not correspond to a maximum open or closed final state). Analog must then, if for one direction no target position is stored - which z. B. for an upward movement into the closed position would be the case if only PZ is stored, but not PO, P1, P2 - be driven in this direction in manual mode. If no target position is stored, eg. B. in a new installation or after a power disconnection, no automatic mode is possible. If the bottom door 7 is moved in automatic mode, an anti-pinch protection is preferably activated.

Automatic mode and manual operation are not mutually exclusive: by permanently actuating the positioning panel (s) 25, 26, the bottom door 7 also moves in manual mode if a target position could be approached in this direction. It can be z. B. a maximum actuation time of the traversing fields 25 and 26, respectively the associated keys 25a, 25b and 26a, 26b, are set to activate the automatic mode, z. B. 0.4 seconds.

A target position PO, P1, P2, PZ may be any position of the bottom door 7 between and including the zero position PO and the maximum open position PZ. However, the maximum stored opening position PZ need not be the position with abutment on the work surface 8. Storing the target position PO, P1, P2, PZ can be achieved with the bottom door 7 at the desired target position PO, P1, P2, PZ, by means of, for example, several seconds (for example, two seconds), actuation. gens a confirmation button 28 in the control panel 12 are performed. Existing optical and / or acoustic signal transmitters which output corresponding signals after storing a target position are not shown for the sake of clarity. A start-up of the desired target position PO, P1, P2, PZ to be set is done, for example, by - in this embodiment - ambidextrous operation of the movement panels 25 and 26 and manual method to this position.

In the memory unit 27, only one or, as shown in this exemplary embodiment game, a plurality of target positions PO, P1, P2, PZ can be einspeicherbar. In the case of a plurality of target positions PO, P1, P2, PZ, these can be approached successively by actuating the corresponding movement keys 25a, 25b or 26a, 26b. By multiple target positions PO, P1, P2, PZ, the high-installation cooking appliance can be easily adapted to the desired operating height of multiple users. The target position (s) are advantageously erasable and / or overwritten. In one embodiment, for example, only one target position can be stored in the opened state, while the zero position PO is automatically detected and can be automatically approached. Alternatively, the zero position PO must be stored in order to be automatically approachable.

It is particularly advantageous for ergonomic use if the or a target position P1, P2, PZ opens the bottom door 7 at least about 400 mm to about 540 mm (ie P1-P0, P2-P0, PZ-PO ≥ 40cm to 54 cm). In this opening dimension the food supports 21 are easy to insert into the support members 20. It is advantageous if the viewing window 4 is mounted approximately at eye level of the user or slightly below, z. B. by means of a template that indicates the dimensions of the cooking appliance.

Not shown is an existing power failure override for bridging approx. 1 to 3 s power failure, preferably up to 1.5 s power failure.

The drive motor 9 from FIG. 1 has at least one sensor unit 31, 32 arranged on a motor shaft 30, possibly in front of or behind a transmission, in order to measure a travel path or a position and / or a speed of the bottom door 7. For example, the sensor unit may include one or more induction, reverberation, opto, SAW sensors, and so forth. Here are two Hall (part) elements 31 by 180 ° for easy travel and speed measurement sets - ie opposite - attached to the motor shaft 30, and a Hallmeßaufnehmer 32 is fixedly mounted at this area of the motor shaft spaced. If a Hall element 31 then moves past the measuring transducer 32 when the motor shaft 30 rotates, a measuring or sensor signal is generated which is, to a good approximation, digital. With (not necessarily) two Hall elements 31, therefore, two signals are output during one revolution of the motor shaft 30. By time evaluation of these signals, z. B. their time difference, the speed vL of the bottom door 7 can be determined, for example via comparison tables or a conversion in real time in the control circuit 13. By addition or subtraction of the measured signals, a travel or a position of the bottom door 7 can be determined.

A speed control can realize the speed, for example via a PWM-controlled power semiconductor.

For zero point determination, the distance measurement is automatically readjusted by initialization in the zero position PO of the bottom door 7 at each startup, so z. B. a faulty sensor signal output or -aufnähme not traditional.

The drive motor 9 is operated by actuation of both traversing panels 25 and 26, even when the main switch 29 is turned off.

Instead of two separate switches per traversing field 25, 26 and a single switch per traversing field is possible, for. B. a toggle switch with a neutral position, which switches only under pressure. Other shapes are possible. Also, the nature and arrangement of the controls 28,29 of the control panel 12 is not limited.

The arrangement and distribution of the control circuit 13 is flexible and not limited, so it can be several boards, z. B. include a display board, a control board and an elevator board, which are spatially separated.

A 4 mm opening dimension can be detected by limit switches 33, which deactivate anti-pinch protection when actuated.

The high-installation cooking appliance can also be designed without a storage unit 27, in which case no automatic operation is possible. This can be for increased operating safety, eg. B. as protection against pinching, be useful. 6 shows a diagram, which is not true to scale, of a plot of the travel speed vL of the bottom door 7 in mm / s against the position of the bottom door in mm from the zero position PO for a movement of the bottom door 7 from the closed state at PO = 0 mm to PZ = maximum opening at 530 mm here in manual travel mode (ie without automatic procedure) and, as indicated by the dotted arrow, stopping the movement between PO and PZ. The curve is traversed in the direction of the arrow, ie from right to left. The downward arrows present above the curve indicate actuations of the control panel 12.

The movement of the bottom door 7 downwards begins with two-handed operation of the movement panels 25, 26 and the ON-switch 25b and 26b, as indicated by the upper left vertical arrow. The control circuit 13 controls the drive motor 9 so that the bottom door 7 gently, d. h .: with a defined ramp R1, is approached to their target speed of here vL = 50 mm / s. The ramp R1 is linear here. The drive motor 9 is therefore not simply turned on.

The movement is characterized load independent, in particular independent of the payload of the bottom door 7 or changed friction conditions of the mechanics. An input for this can be the speed of the drive motor 9, the z. B. can be measured by Hall sensors.

After reaching the desired speed of vL = 50 mm / s, the bottom door 7 constantly moves downwards until it approaches the maximum opening PZ, which results from the design-dictated maximum travel of the bottom door 7 or reaching the worktop 8. In this figure, it is assumed that the constructive maximum opening PZ is achieved. In this case, the control circuit 13 recognizes this approach and brakes the bottom door 7 automatically, d. H. with a defined ramp R2, down to PZ. Both ramps R1 and R2 may have other slopes or shapes. The approach to the bottom plate can be detected by limit switch 33 and / or by monitoring the travel.

If one or both of the travel switches 25b, 26b is released, as indicated by the upper left vertical arrow, the bottom door 7 abruptly stops without a ramp, as indicated by the dotted arrow. So in this mode will be Although gently approached, but - except when reaching the final position - abruptly stopped.

The cooking chamber 3 is not opened, the bottom door 7 so do not proceed from the zero position PO when an opening assurance is active, so if, for example, a certain temperature in the oven, z. B. 425 ⁰ C or 600 ⁰ F, is exceeded or a child safety device is activated.

FIG. 7 shows a diagram, which is analogous to FIG. 6 and not to scale, for a method of moving the bottom door 7 from the closed state to a stored position P1 = 476 mm in automatic travel operation.

In this case, by briefly pressing one of the UP switches 25b or 26b, as indicated by the upper right vertical arrow, the bottom door 7 automatically begins to move to the position P1. Again, the bottom door 7 is gently approached (right ramp) and automatically braked (left ramp). In this embodiment, in automatic mode, it is possible to choose between two fixed set speeds, namely 75 mm / s (dashed line) and 50 mm / s (solid line), the slower speed being favorable, in particular, for older users. Default, z. B. at delivery, is the slower speed level. It can also be provided more than two speed levels or target speeds; Also, a free adjustment of the desired speed (s) by the user is conceivable. Conveniently, at least between two speed levels of 50 mm / s and 65 mm / s switchable, z. B. at a device initialization.

8 shows a diagram, which is not true to scale, for a method of the base door 7 from the maximum opening position PZ to the zero position PO, ie in the closed state, in manual operation.

The movement of the bottom door 7 upward begins with two-handed operation of the to-switch 25a and 26a, as indicated by the upper left vertical arrow. The control circuit 13 controls the drive motor 9 so that the bottom door 7 is gently approached from PZ to its desired speed of vL = 50 mm / s, and then with this target speed constant (to the right) is moved. The control circuit 13 detects an approach to the zero position PO and brakes the bottom door 7 in good time before. But instead of using the linear ramp to shift directly down to the zero position PO, the speed-dependent control is switched to control with a defined voltage 4 mm before the zero position PO, ie by supplying the motor 9 with a corresponding voltage. This allows a maximum force development when blocking the drive motor 9 set. This voltage differs depending on the history of the process (payload, friction conditions, etc.). The detection of the 4 mm opening dimension takes place via the travel measurement or additionally or alternatively via the limit switches 33. In the range of PO to PO + 4 mm, an anti-pinch protection can also be dispensed with.

If, as in Fig. 6, one or both of the travel switches 25b, 26b is released, as indicated by the upper right vertical arrow, the bottom door 7 abruptly stops without ramp, as indicated by the dotted arrow.

9 shows a diagram, which is not true to scale, for a method of moving the bottom door 7 from a stored position P1 = 476 mm into the closed state PO in automatic travel operation. In contrast to the manual traversing operation shown in FIG. 8, only one of the CLOSE switches 25a, 26a now needs to be actuated for a short time, as indicated by the upper vertical arrow. Then moves the bottom door 7 analogous to Fig. 7, only in the other direction. When approaching the zero position PO, the deceleration ramp for the last 4 mm opening changes from a speed-controlled state into a load- or closing-force-controlled state analogously to the situation from FIG. 8.

FIG. 10 shows a diagram analogous to FIG. 8, in which jamming now occurs at a setpoint speed of vL = 50 mm / s, as indicated by the upper vertical arrow. When pinching, for example, a hand or a pot, etc. between the bottom door 7 and the housing 1, the speed of the bottom door 7 drops, since the object obstructs another method. The monitoring of the lift speed happens here, for example, by evaluating the sensor signals of the motor shaft, wherein z. B. the time between the measurement signals or pulses is evaluated. Only in the second instance is the motor current monitored, which is a rather slower method. In particular, the force that can be generated by the motor 9 for the method is limited in order to avoid accidents due to excessive clamping (see also FIGS. 12 and 13). The Deviation from the desired speed is detected by the control circuit 13, z. B. by a speed deviation or a temporal change in speed. Then reverses the bottom door, so that the object can be removed; if necessary, a, z. B. issued audible, warning signal. The bottom door 7 then moves on only when a corresponding actuation of a movement load field 25, 26 again.

Thus the Einklemmfall is not triggered by mistake, z. Firstly, the anti-trapping device can only be actively activated when the bottom door 7 has reached its setpoint speed (if a traversing button 25a, 25b, 26a, 26b is released beforehand, the bottom door remains open due to a changed payload or a change in the running properties of the mechanism 7 immediately stand), and it may be secondly evaluated several sensor signals, for example, averaged.

Fig. 1 1 shows the Einklemmfall (upper vertical arrow) in the opening process of the bottom door 7 in automatic mode to a target position P1, in which an object between the bottom of the bottom door 7 and the worktop 8 is clamped. In this case, the Einklemmerkennung can be done via two redundant limit switches, which recognize a - especially non-uniform - relief of the bottom door 7, whereupon the drive motor 9 reverses. The maximum permissible force time profile (see FIGS. 12 and 13) is not exceeded.

FIG. 12 shows a force F in N which can be applied maximally to the bottom door 7 in the trapping case during the process in a closing direction (ie upwards) in relation to the elapsed time t in s as a first force time profile FT1.

In case of trapping at t = 0 s, the possible closing force is limited to 100 N, corresponding to approx. 10 kg, for 5 s. This is z. B. useful if the motor 9 is up-regulated by the controller 13 to hold the target speed. This ensures in particular that body parts are not injured. If the floor door is tightened for a maximum of 100 N for 5 s, the maximum force that can be applied is reduced further to 25 N, eg. For 5 seconds. In the following, this level of force can be kept or z. B. continue to be lowered to 0 N. It should be emphasized that this force time profile FT1 indicates only the maximum applicable force, and the actually applied force is usually lower, for. B. if the Einklemmfall detected by the controller 13, and the bottom door 7 after t = 0.5 s is reversed accordingly, whereupon the applied force of 100 N to z. B. 0 N decreases.

The maximum force threshold of 100 N can also apply to other traversing situations.

FIG. 13 shows a force F in N which can be applied to the bottom door 7 in the event of trapping in the process in an opening direction (that is, downwards) against the elapsed time t in s as a second force time profile FT2. Here, the drive motor 9 in a first block of t = [0 s; 0.5 s] up to 400 N to the bottom door 7, then at t = [0.5 s; 5 s] 150 N and then 25 N.

Of course, the time intervals and force threshold values of the force time profiles FT1, FT2 can be adapted to the structure and further boundary conditions.

LIST OF REFERENCES

1 housing

2 wall

3 cooking space

4 viewing window

5 muffles

6 muffle opening

7 bottom door

8 worktop

9 drive motor

10 lifting element

11 control element

12 control panel

13 control circuit

14 ad elements

15 hob

16 hotplate radiators

17 hotplate radiators

18 surface heating elements

19 glass ceramic plate

20 mounting part

21 food support

22 top heaters

23 fans

24 seal

25 traversing panel

25a travel switch upwards

25b Travel switch down

26 traversing panel

26a Travel switch upwards

26b Travel switch down

27 storage unit

28 confirmation button

29 main switch

30 motor shaft

31 Hall element 32 transducers

33 limit switch

FT1 first time-force profile

FT2 second power time profile PO zero position

P1 between position

P2 between position

PZ E nd position

R1 Velocity ramp R2 Velocity ramp vL Traversing speed of the bottom door

Claims

claims

1. cooking appliance, in particular high-installation cooking appliance, with at least one cooking chamber (3) delimiting muffle (5) with a muffle opening (6), a door (7) for closing the muffle opening (6) and controlled by a control circuit (13) Antriebsei device (9,10) for moving the door (7), characterized in that the drive means (9, 10) by the control circuit (13) is adjustable so that a predetermined Verfahrparameter the door (7) by at least one defined ramp (R1, R2) can be controlled.

2. Cooking appliance according to claim 1, characterized in that the Verfahrpa- parameter is a traversing speed (vL).

3. Cooking appliance according to claim 2, characterized in that when a start of the door (7) to a desired speed, a first defined speed ramp (R1) is durchfahrbar.

4. Cooking appliance according to claim 2 or 3, characterized in that when stopping the door (7) to a further desired speed, a second defined speed ramp (R2) is durchfahrbar.

5. cooking appliance according to one of claims 2 to 4, characterized in that the door (7) after actuation of a traversing panel (25, 26) by means of the first speed ramp (R1) can go to a desired speed and the target speed by means of the second speed ramp ( R2) can automatically come to a standstill.

6. Cooking appliance according to one of claims 2 to 5, characterized in that the door (7) during operation of at least one traversing panel (25, 26) by means of the first speed ramp (R1) can go to a desired speed and after releasing at least one traversing panel ( 25, 26) can come to an abrupt halt.

7. Cooking appliance according to one of claims 2 to 6, characterized in that the travel speed (vL) by means of a Geschwindigkeitsmeßvorrichtung (31, 32) can be detected, the at least one on a motor shaft (10) of a drive motor (9) of the drive means (9, 10), in particular a Hall sensor (31, 32).

8. Cooking appliance according to one of claims 2 to 7, characterized in that the travel speed (vL) is user adjustable.

9. Cooking appliance according to one of claims 2 to 8, characterized in that pinching on the door (7) by monitoring the traversing speed (vL) is detectable.

10. cooking appliance according to claim 9, characterized in that a pinch contactor is activated only when the target speed of the door (7) is reached.

11. Cooking appliance according to one of the preceding claims, characterized in that a movement of the door (7) between a speed-dependent movement and a load-dependent movement is switchable.

12. Cooking appliance according to one of the preceding claims, characterized in that the cooking appliance is designed as a high-installation cooking appliance, wherein the muffle opening (6) is arranged on the bottom side, and the door for closing the Muf- felöffnung (6) has a lowerable bottom door (7). is.

13. A method for operating the cooking appliance according to one of the preceding claims, characterized in that the door (7) by at least one defined ramp, in particular a speed ramp (R1) is approached and / or by a further defined ramp, in particular a speed ramp (R2 ), is stopped.